Stochasticity and heterogeneity restrict tipping points and alternative stable states

Authors

Das, S., Shnerb, N., DeMalach, N.

Abstract

Gradual environmental stress may trigger abrupt tipping points, trapping ecosystems in degraded states that are difficult to reverse. This possibility has strongly influenced ecosystem management, yet empirical evidence for such behavior remains mixed. A major unresolved question is how broadly stochasticity and heterogeneity restrict hysteresis, and whether their effects accumulate. To address it, we reconstructed full phase diagrams for four canonical ecological models (dryland desertification, grazing, insect outbreaks, and lake eutrophication) across gradients of stress, demographic stochasticity, environmental fluctuations, spatial heterogeneity, and dispersal. In every model, stochasticity and heterogeneity narrowed the region supporting alternative stable states and made the remaining transition less abrupt. Dispersal set their effective strength by averaging across space. These complexities eroded hysteresis along different routes -toward the degraded state, through a continuous transition, or, counterintuitively, toward the healthy state. Effects were largely additive, so several moderate complexities could eliminate hysteresis even when no single factor did. Tipping-point claims should therefore be tested under stochastic, heterogeneous conditions.

Preprint server: bioRxiv
The authors list and abstract were imported from bioRxiv on 20 Jun 2026.

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